EP0038980A1 - Mechanical welding-device for the support of the weld pool - Google Patents

Abstract

The invention provides a device for securing the weld pool during mechanized welding in a forced position, in particular in an upright, for example in a vertical position, with sliding shoes pressed against the surface of the workpieces 38, 44 to be welded, which feed the welding current and the welding electrode and which move at the welding speed consist of two segments 8, 19 which are close to each other and are mutually movable in the at least approximately vertical central plane of the welding gap 51 between the workpieces 38, 44, the slide shoe segments 8, 19 being individually and independently movable to the surface of one workpiece 38 each or 44 are pressed softly.

Description

The invention relates to a device for securing the weld pool during mechanical welding in a forced position, in particular in an upright position; for example vertical position; the device has sliding shoes pressed against the surface of the workpieces to be welded, feeding the welding current and the welding electrode and moving at welding speed, which consist of two segments that are close together and are mutually movable in the at least approximately perpendicular central plane of the welding gap between the workpieces.

Such a device is given in German Patent Application 1 165 786; Above all, it is intended to influence the pressing force of the two-part sliding shoes on the workpieces to be welded in such a way that it is always optimal even with an irregular, for example curved, shape of the workpieces. The segments are pressed on using a complex lever mechanism with a single compression spring on each side; since the segments can only be moved relative to one another to a limited extent, a good and uniform weld seam cannot be produced if the two workpiece edges to be welded have a large edge offset or the workpieces are significantly inclined to one another; leakage of the melt from the side cannot be avoided with certainty.

A good lateral sealing of the weld pool is admittedly achieved with the device according to German patent specification 1 096 515 and German patent specification 1 108 352; however, since the area directly on the melting line is not adequately cooled in the event of sheet unevenness, large fluctuations in the penetration depth occur. The otherwise known attachment of additional guideways increases idle times significantly and is not suitable for all applications.

In the device according to the German patent specification 2 603 02 ₀ , a good seal against leakage of the melt pool is guaranteed by segmenting the sliding surfaces, but because of the large-area friction of the individual segments on one another, the contact forces cannot be determined exactly.

The object of the invention is to improve the device of the type mentioned at the outset so that even large inaccuracies with regard to the surfaces of the workpieces to be welded can be mastered with little effort, so that a good weld seam is also produced in these cases.

This object is achieved with a device for securing the weld pool during mechanized welding in a forced position, in particular in an upright, for example vertical position, with sliding shoes which are pressed against the surface of the workpieces to be welded and which feed the welding current and the welding electrode and move at the welding speed at least approximately vertical central plane of the welding gap between the workpieces lying close together, mutually movable segments, solved by the fact that the sliding shoe segments are individually and independently movably pressed against the surface of a workpiece. The segments, which can be moved individually and independently of one another on the surface of each workpiece, reliably compensate for any errors that occur in practice, particularly in the mutual position of the workpieces, such as edge offset and inclination, so that a good weld seam is always guaranteed.

In particular, the mobility of the sliding shoe segments can be achieved in such a way that the sliding shoe segments are each guided by a swivel joint with an axis perpendicular to the central plane of the welding gap and parallel to the central plane individually tiltable and in the direction of the workpiece are connected in parallel with a common holder, which is arranged by means of an extension piece in a machine frame in the longitudinal direction of the welding gap. In particular, it is provided that the guidance of the sliding shoe segments parallel to the central plane of the welding gap comprises two pins located opposite one another in a plane parallel to the central plane of the welding gap, each of which engages in a slot lying in this plane towards the workpiece, these slots on a projection of the common holder, optionally with adjustable end stops, are formed. Here, the design can be such that compression springs, in particular pneumatic or hydraulic cylinders, are fitted between each sliding shoe segment and the common holder.

Coolant can also flow through the sliding shoe segments, for which purpose they are provided with corresponding flow channels for the coolant.

In addition, in order to prevent leakage of the metal and slag bath through the common longitudinal groove of the two segments during ignition of the welding process, the device according to the invention can be designed such that a sealing body is resiliently attached to the underside of each sliding shoe segment so that it is pushed back obliquely downwards by an excessive welding bead, and that these sealing bodies are close to one another in the central plane of the welding gap and, as an extension of a common central longitudinal groove of the sliding shoe elements, have a common longitudinal groove which runs obliquely in front of the lower end of each sealing body. In particular, the sealing bodies can be attached in such a way that the sealing bodies are each guided by a bolt, which points obliquely downwards and is fastened in the associated sliding shoe segment, and are pressed onto the latter by a spring with a washer and a split pin.

In addition, it is possible that, for special applications, an additional segment, constructed in the same way, is attached laterally to each sliding block segment in a tight and independently movable manner and is fastened by means of an extended common holder.

An additional device for inert gas welding can also be provided.

According to German patent specification 1 140 297 and German design specification 1 565 893, the protective gas is supplied through the sliding block into the arc area of the welding gap. This has the disadvantage that with longer seams and narrower welding gaps, the shielding gas openings become more or less clogged by splashes, which can lead to turbulence, which can cause pores in the weld metal, for example. In order to eliminate this disadvantage, the protective gas is fed to the welding process directly above the sliding shoe according to the invention. For this purpose, the device according to the invention is designed in such a way that a protective gas supply nozzle, which is preferably expanded in the direction of flow and bent at the end, is placed on each sliding shoe segment such that they lie movably close to one another in the central plane of the welding gap.

In order to avoid an injector effect, the gas supply is sealed off from the outside. Specifically, this can be done in such a way that the protective gas supply nozzles are at least partially formed from baffles which are held in a housing which is firmly connected to a sliding shoe segment. Preferably, the rear abutting edge of the two protective gas supply nozzles is bridged by a resilient sealing cap is. Here, the housing of the protective gas supply nozzles can be assembled with a cabin housing divided in the central plane of the welding gap, the parts of which are fastened to a sliding shoe segment at the top.

A certain excess pressure is maintained in the welding area by means of a pressure switch, so that ambient air cannot enter. Special attention is paid to sealing off from the surroundings. Sealed inspection openings are provided when a welding booth is formed.

• (a) daß das Kabinengehäuse eine Drahtelektroden-Zuführung trägt;
• (b) daß das Kabinengehäuse einen die Schutzgas-Zufuhr steuernden Druckwächter trägt;
• (c) daß das Kabinengehäuse oben eine Absaugöffnung für entweichendes Schutzgas und Rauchgas trägt;
• . (d) daß wenigstens eines der beiden Teile des Kabinengehäuses eine mit einem Schauglas versehene Öffnung trägt; und
• (e) daß an den Gehäusen von Kabine und Schutzgas-Zufuhrdüsen seitlich je eine Abdichtleiste anliegt, die mittels Bolzen und damit zusammenwirkenden, in Richtung auf die Werkstücke verlaufenden Schlitzen geführt und durch Federn an die Werkstücke angedrückt werden, wobei die Federn zum Beispiel durch je einen Bolzen an jenen Gehäusen gehalten sind.

The welding booth can be designed

• (a) that the cabin housing carries a wire electrode feed;
• (b) that the cabin housing carries a pressure switch which controls the supply of protective gas;
• (c) that the cabin housing carries a suction opening for escaping protective gas and flue gas;
• . (d) that at least one of the two parts of the cabin housing has an opening provided with a sight glass; and
• (e) that on the housings of the cabin and shielding gas supply nozzles there is a sealing strip on each side, which is guided by means of bolts and cooperating slots that run in the direction of the workpieces and are pressed onto the workpieces by springs, the springs being pressed, for example, by each a bolt is held on those housings.

• Figur 1 schematisch die Bewegungsmöglichkeiten der erfindungsgemäßen Gleitschuhvorrichtung;
• Figur 2 einen Längsschnitt durch eine zweigeteilte Gleitschuhvorrichtung gemäß der gebrochenen Linie II-II in Figur 3;
• Figur 3 diese Gleitschuhvorrichtung in Ansicht von hinten;
• Figur 4 eine viergeteilte Gleitschuhvorrichtung mit den Bewegungsmöglichkeiten nach Figur 1, und zwar in Draufsicht;
• Figur 5 eine zweigeteilte Gleitschuhvorrichtung mit Schutzgaszufuhr für das Elektrogasschweißen, und zwar in Ansicht von vorn;
• Figur 6 einen Teillängsschnitt gemäß Linie III-III in Figur 5;
• Figur 7 einen Teilquerschnitt gemäß Linie I-I in Figur 5; und
• Figur 8 eine zweigeteilte Gelitschuhvorrichtung mit Abdichteinrichtung für den Schweißbereich beim Elektrogasschweißen.

Finally, the design can be such that bores for receiving phototransistors or thermocouples are provided in the common longitudinal groove of the sliding shoe segments located in the area of the welding gap, which are used to control the welding speed and the supply of welding powder, as a result of which the phototransistors or thermocouples are installed in a manner protected against the welding heat. The invention is explained in more detail below with some preferred exemplary embodiments with reference to the drawings; show:

• Figure 1 shows schematically the possibilities of movement of the slide shoe device according to the invention;
• Figure 2 shows a longitudinal section through a two-part sliding shoe device according to the broken line II-II in Figure 3;
• Figure 3 shows this shoe device in rear view;
• FIG. 4 shows a four-part sliding shoe device with the movement possibilities according to FIG. 1, namely in a top view;
• FIG. 5 shows a two-part sliding shoe device with protective gas supply for electric gas welding, specifically in a view from the front;
• FIG. 6 shows a partial longitudinal section along line III-III in FIG. 5;
• FIG. 7 shows a partial cross section along line II in FIG. 5; and
• FIG. 8 shows a two-part gel shoe device with a sealing device for the welding area in electric gas welding.

In Figure 1, the possibilities of movement of the slide shoe according to the invention can be seen schematically. In a holder 10 shown in FIGS. 2, 3 and 8, which also guides the two gel shoe segments 8 lying against one another in the central plane of the welding gap 51 (see FIG. 8), 19 and takes over the power transmission from a machine frame, not shown, each segment can move independently of the other in two directions, from a starting position 1, in which the segments are pressed against the workpieces 38, 44 to be welded with surfaces lying in one plane are. If these surfaces are not in one plane during the welding process, the segments are automatically moved so that they always remain pressed on with their entire surface. With a parallel edge offset, one segment moves parallel to position 2 and the other segment to the rear. Deviates the contour of a sheet of swine _ß ung from that of the other plate from, then each segment will be able to move parallel to the front in the position 2 or to the back or to perform a rotation, wherein the segment upper edge in the clockwise direction in the Position 3 or counterclockwise to position 4. With these movement options, unevenness in the sheet that is larger than the segment length and a large edge offset can be reliably compensated.

The movement mechanism according to the invention is shown in Figures 2 and 3. In the holder 10 provided with an attachment 5 for fastening in a machine frame, the sliding shoe segments 8, 19 are provided by two pins 7, 13 and 20, 24 opposite in a plane II-II and IV-IV parallel to the central plane of the welding gap 51 guided laterally in slots 7 ', 13' and 20 ', 24'; the pins are firmly attached to the sliding shoe segments 8, 19. The associated slots 7 ', 13' and 20 ', 24' in each of these protrusions 10 'of the holder 10, which are located in these planes in the direction of the workpieces 38 and 44, are dimensioned such that they serve as end stops and do not stretch or longitudinal displacement of the segments, but allow tilting about their central axis.

One pin 11 or 22, which is perpendicular to the center plane of the welding gap 51, engages in two central slots 11 'or 22 'of the holder 10; these are formed in two spaced-apart planes parallel to the central plane of the welding gap in the direction of the workpieces and likewise have end stops. This allows both the tilting and the parallel movement of the segments, whereby the necessary welding feed force is transmitted.

The required pressing force is transmitted from the machine frame via the holder 10, two springs 9, 12 and 21, 23 each with adjustable preload and the two segments 8 and 19 to the workpieces 38 and 44, which have the welding gap 51 between them . In this area, the segments delimit in a known manner a common longitudinal groove 15, which enables the formation of a well-shaped weld seam. Below the segments, two sealing bodies 16 and 25 are attached, which, like the segments, are divided and connected to them. These sealing bodies also delimit a common longitudinal groove 15 ′ which is aligned with the longitudinal groove 15 and runs out obliquely in front of the lower end of each sealing body. The two sealing bodies are guided by diagonally arranged bolts 14 and 26. One spring 17 or 27, held by a washer with a split pin 18 or 28, presses the sealing body against the corresponding segment 8 or 19, so that they are pushed back through their longitudinal groove when an excessive weld seam occurs, without the Sealing effect suffers significantly.

In order to achieve a better sealing effect of particularly low-viscosity melts, two further segments 41 and 42 are laterally attached to the two segments 8, 19 in a tight and independently movable manner and guided in an expanded common holder 10a. These additional segments generally do not have coolant flow channels 6 like the inner segments 8, 19, since too much heat should not be removed from the workpieces; and the The additional segments 41 and 42 are preferably attached to the holder 10a in the same way as the segments 8 and 19.

FIGS. 5 to 7 show a sliding shoe device with a protective gas supply for electric welding. Gas supply nozzles 30, 29 are mounted on the slide shoes 8 and 19 so that they follow their movements; they are therefore formed in the same way in the center plane of the weld 51 separately and designed with baffles 40 and 39 so that they are sealed from the environment. Therefore, the rear abutting edge of these nozzles is bridged by a flexible sealing cap 31. In order to reduce the outlet speed of the protective gas, the nozzles are widened in a funnel shape. In order to prevent an undesired injector effect, the outflow ends of the nozzles are bent over so that they are not directed directly at the welding point.

For electric gas welding, it is advantageous if a small cabin, which is divided in the same way as the sliding shoes and is connected to the segments 32 and 49, is used for the welding area, as shown in FIG. The gas supply nozzles are then integrated in the cabin segments. The protective gas loss is kept extremely low by side sealing strips 34 and 37; they are each guided by two bolts 45 in a slot 48 and pressed by a spring 46 against the workpieces 38 and 44 respectively. The springs are held by a bolt 47 on the cabin. The welding process can be easily observed through an opening 33 or 50 in the cabin, which is closed with a sight glass.

A pressure monitor 36 attached to the cabin from the segments 32, 49 continuously maintains a low protective gas overpressure in it. Through the cabin wall is further a wire electrode feed 35 passed. A suction opening 43 is provided on the cabin for the extraction of protective gas and smoke gas escaping.

Claims (19)

1. Device for securing the weld pool during mechanized welding in a forced position, in particular in an upright, for example in a vertical position, with sliding shoes which are pressed against the surface of the workpieces to be welded, feed the welding current and the welding electrode and move at welding speed and which consist of two in the at least approximately vertical central plane of the welding gap between the workpieces lying close together, mutually movable segments, characterized in that the sliding shoe segments (8, 19) are individually and independently of one another flexibly pressed against the surface of one workpiece (38 or ⁴⁴ ). 2. Device according to claim 1, characterized in that the sliding shoe segments (8,19) by means of a swivel joint with an axis perpendicular to the central plane of the welding gap (51) and parallel to the central plane, individually tiltable and displaceable parallel to the workpiece (38 or 44), connected to a common holder (10) which is connected by means of an extension piece (5) is slidably arranged in a machine frame in the longitudinal direction (A) of the welding gap. 3. Apparatus according to claim 2, characterized in that the swivel joint contains a pin (11 or 22) perpendicular to the central plane of the welding gap (51), which in at least one central slot (11 'or 22') in the common holder (10 ) engages, which is formed lying in a plane parallel to the central plane of the welding gap in the direction of the workpiece (38 or 44) and optionally has adjustable end stops. 4. Apparatus according to claim 2 or 3, characterized in that the guide of the sliding shoe segments (8, 19) parallel to the central plane of the welding gap (51) has two pins (7, 13 or in a plane parallel to the central plane of the welding gap (51). 20, 24) which each engage in a slot (7 ', 13' or 20 ', 24') lying in this plane in the direction of the workpiece (38 or 44), these slots on a projection (10 ') of the common holder (10), optionally with adjustable end stops. 5. Device according to one of claims 2 to 4, characterized in that between each sliding shoe segment (8,19) and the common holder (10) compression springs (9,12 or 21,23), in particular pneumatic or hydraulic cylinders, are attached . 6. Device according to one of claims 1 to 5, characterized in that the sliding shoe segments (8, 19) have flow channels (6) for a coolant. 7. Device according to one of claims 1 to 6, characterized in that on the underside of each sliding shoe segment (8,19) a sealing body (16 or 25) is resiliently attached so that it is pushed back obliquely by an excessive welding bead , and that these sealing bodies in the central plane of the welding gap (51) close to each other and in extension of a common central longitudinal groove (15) of the sliding shoe segments have a common longitudinal groove (15 ') which runs obliquely in front of the lower end of each sealing body. 8. The device according to claim 7, characterized in that the sealing body (16, 25) by a respective obliquely downward, in the associated sliding shoe segment. (8 and 19) attached bolts (14 and 26) guided and by a spring (17 or 27) with washer and split pin (18 or 28) can be pressed onto it (Figure 3). 9. Device according to one of claims 1 to 8, characterized in that each slide shoe segment (8, 19) has an additional, similarly constructed segment (41 or 42) laterally and independently movably attached and by means of an extended common holder (10a) is attached (Figure 4). 10. Device according to one of claims 1 to 9, characterized in that on each sliding shoe segment (8, 19) a protective gas supply nozzle (30 or 29), preferably expanded in the flow direction and bent at the end, is placed in such a way that it is in the middle plane of the welding gap (51) are movable close to each other (Figure 5). 11. The device according to claim 10, characterized in that the protective gas supply nozzles (30, 29) are at least partially formed from baffles (40 or 39) which in a housing with a sliding shoe segment (8 or 19) firmly connected ( 40 'or 39') are held. 12. The apparatus of claim 10 or 11, characterized in that the rear abutting edge of the two protective gas supply nozzles (30, 29) is bridged by a resilient sealing cap (31) (Figure 7). 13. Device according to one of claims 10 to 12, characterized in that the housing (40 ', 39') of the protective gas supply nozzles (30 or 29) are assembled with a in the central plane of the welding gap (51) divided cabin housing, the Parts (32, 49) are each attached to a slide shoe segment (8 or 19) at the top (FIG. 8). 14. The apparatus according to claim 13, characterized in that the cabin housing carries a wire electrode feed (35). 15. The apparatus according to claim 13 or 14, characterized in that the cabin housing carries a protective gas supply controlling pressure switch (36). 16. The device according to one of claims 13 to 15, characterized in that the cabin housing carries a suction opening (43) above for escaping protective gas and flue gas. 17. The device according to one of claims 13 to 16, characterized in that at least one of the two parts (32, 49) of the cabin housing has an opening (33 or 50) provided with a sight glass. ₁ 8. Device according to one of claims 13 to 17, characterized in that on the housings (32, 40 'and 49, 39') of, cabin and inert gas supply nozzles each have a sealing strip (34 or 37), the slots (48) are guided by means of bolts (45) and cooperate therewith and extend in the direction of the workpieces (38 or 44) and are pressed against the workpieces by springs (46), the springs being each, for example, by a bolt (47 ) are held on those housings. 19. Device according to one of claims 1 to 18, characterized in that in the area of the welding gap. (51) lying common longitudinal groove (15) of the sliding shoe segments (8,19) bores (52) for receiving phototransistors or thermocouples are used, which are used to control the welding speed and welding powder supply.

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